Tasmota/tasmota/xnrg_12_solaxX1.ino

/*
  xnrg_12_solaxX1.ino - Solax X1 inverter RS485 support for Tasmota

  Copyright (C) 2020  Pablo Zerón

  This program is free software: you can redistribute it and/or modify
  it under the terms of the GNU General Public License as published by
  the Free Software Foundation, either version 3 of the License, or
  (at your option) any later version.

  This program is distributed in the hope that it will be useful,
  but WITHOUT ANY WARRANTY; without even the implied warranty of
  MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
  GNU General Public License for more details.

  You should have received a copy of the GNU General Public License
  along with this program.  If not, see <http://www.gnu.org/licenses/>.
*/

#ifdef USE_ENERGY_SENSOR
#ifdef USE_SOLAX_X1
/*********************************************************************************************\
 * Solax X1 Inverter
\*********************************************************************************************/

#define XNRG_12            12

#ifndef SOLAXX1_SPEED
#define SOLAXX1_SPEED      9600      // default solax rs485 speed
#endif

#define INVERTER_ADDRESS   0x0A

#define D_SOLAX_X1         "SolaxX1"

#include <TasmotaSerial.h>

enum solaxX1_Error
{
  solaxX1_ERR_NO_ERROR,
  solaxX1_ERR_CRC_ERROR
};

union {
  uint32_t ErrMessage;
  struct {
    //BYTE0
    uint8_t TzProtectFault:1;//0
    uint8_t MainsLostFault:1;//1
    uint8_t GridVoltFault:1;//2
    uint8_t GridFreqFault:1;//3
    uint8_t PLLLostFault:1;//4
    uint8_t BusVoltFault:1;//5
    uint8_t ErrBit06:1;//6
    uint8_t OciFault:1;//7
    //BYTE1
    uint8_t Dci_OCP_Fault:1;//8
    uint8_t ResidualCurrentFault:1;//9
    uint8_t PvVoltFault:1;//10
    uint8_t Ac10Mins_Voltage_Fault:1;//11
    uint8_t IsolationFault:1;//12
    uint8_t TemperatureOverFault:1;//13
    uint8_t FanFault:1;//14
    uint8_t ErrBit15:1;//15
    //BYTE2
    uint8_t SpiCommsFault:1;//16
    uint8_t SciCommsFault:1;//17
    uint8_t ErrBit18:1;//18
    uint8_t InputConfigFault:1;//19
    uint8_t EepromFault:1;//20
    uint8_t RelayFault:1;//21
    uint8_t SampleConsistenceFault:1;//22
    uint8_t ResidualCurrent_DeviceFault:1;//23
    //BYTE3
    uint8_t ErrBit24:1;//24
    uint8_t ErrBit25:1;//25
    uint8_t ErrBit26:1;//26
    uint8_t ErrBit27:1;//27
    uint8_t ErrBit28:1;//28
    uint8_t DCI_DeviceFault:1;//29
    uint8_t OtherDeviceFault:1;//30
    uint8_t ErrBit31:1;//31
  };
} ErrCode;

const char kSolaxMode[] PROGMEM = D_WAITING "|" D_CHECKING "|" D_WORKING "|" D_FAILURE;

const char kSolaxError[] PROGMEM =
  D_SOLAX_ERROR_0 "|" D_SOLAX_ERROR_1 "|" D_SOLAX_ERROR_2 "|" D_SOLAX_ERROR_3 "|" D_SOLAX_ERROR_4 "|" D_SOLAX_ERROR_5 "|"
  D_SOLAX_ERROR_6 "|" D_SOLAX_ERROR_7 "|" D_SOLAX_ERROR_8;

/*********************************************************************************************/

TasmotaSerial *solaxX1Serial;

uint8_t solaxX1_Init = 1;

struct SOLAXX1 {
  float temperature = 0;
  float energy_today = 0;
  float dc1_voltage = 0;
  float dc2_voltage = 0;
  float dc1_current = 0;
  float dc2_current = 0;
  float energy_total = 0;
  float runtime_total = 0;
  float dc1_power = 0;
  float dc2_power = 0;

  uint8_t status = 0;
  uint32_t errorCode = 0;
} solaxX1;

union {
  uint8_t status;
  struct {
    uint8_t freeBit7:1; // Bit7
    uint8_t freeBit6:1; // Bit6
    uint8_t freeBit5:1; // Bit5
    uint8_t queryOffline:1; // Bit4
    uint8_t queryOfflineSend:1; // Bit3
    uint8_t hasAddress:1; // Bit2
    uint8_t inverterAddressSend:1; // Bit1
    uint8_t inverterSnReceived:1; // Bit0
  };
} protocolStatus;

uint8_t header[2] = {0xAA, 0x55};
uint8_t source[2] = {0x00, 0x00};
uint8_t destination[2] = {0x00, 0x00};
uint8_t controlCode[1] = {0x00};
uint8_t functionCode[1] = {0x00};
uint8_t dataLength[1] = {0x00};
uint8_t data[16] = {0};

uint8_t message[30];

/*********************************************************************************************/

bool solaxX1_RS485ReceiveReady(void)
{
  return (solaxX1Serial->available() > 1);
}

void solaxX1_RS485Send(uint16_t msgLen)
{
  memcpy(message, header, 2);
  memcpy(message + 2, source, 2);
  memcpy(message + 4, destination, 2);
  memcpy(message + 6, controlCode, 1);
  memcpy(message + 7, functionCode, 1);
  memcpy(message + 8, dataLength, 1);
  memcpy(message + 9, data, sizeof(data));
  uint16_t crc = solaxX1_calculateCRC(message, msgLen); // calculate out crc bytes

  while (solaxX1Serial->available() > 0)
  { // read serial if any old data is available
    solaxX1Serial->read();
  }

  solaxX1Serial->flush();
  solaxX1Serial->write(message, msgLen);
  solaxX1Serial->write(highByte(crc));
  solaxX1Serial->write(lowByte(crc));
  AddLogBuffer(LOG_LEVEL_DEBUG_MORE, message, msgLen);
}

uint8_t solaxX1_RS485Receive(uint8_t *value)
{
  uint8_t len = 0;

  while (solaxX1Serial->available() > 0)
  {
    value[len++] = (uint8_t)solaxX1Serial->read();
  }

  AddLogBuffer(LOG_LEVEL_DEBUG_MORE, value, len);

  uint16_t crc = solaxX1_calculateCRC(value, len - 2); // calculate out crc bytes

  if (value[len - 1] == lowByte(crc) && value[len - 2] == highByte(crc))
  { // check calc crc with received crc
    return solaxX1_ERR_NO_ERROR;
  }
  else
  {
    return solaxX1_ERR_CRC_ERROR;
  }
}

uint16_t solaxX1_calculateCRC(uint8_t *bExternTxPackage, uint8_t bLen)
{
  uint8_t i;
  uint16_t wChkSum;
  wChkSum = 0;

  for (i = 0; i < bLen; i++)
  {
    wChkSum = wChkSum + bExternTxPackage[i];
  }
  return wChkSum;
}

void solaxX1_SendInverterAddress(void)
{
  source[0] = 0x00;
  destination[0] = 0x00;
  destination[1] = 0x00;
  controlCode[0] = 0x10;
  functionCode[0] = 0x01;
  dataLength[0] = 0x0F;
  data[14] = INVERTER_ADDRESS; // Inverter Address, It must be unique in case of more inverters in the same rs485 net.
  solaxX1_RS485Send(24);
}

void solaxX1_QueryLiveData(void)
{
  source[0] = 0x01;
  destination[0] = 0x00;
  destination[1] = INVERTER_ADDRESS;
  controlCode[0] = 0x11;
  functionCode[0] = 0x02;
  dataLength[0] = 0x00;
  solaxX1_RS485Send(9);
}

uint8_t solaxX1_ParseErrorCode(uint32_t code){
  ErrCode.ErrMessage = code;

  if (code == 0) return 0;
  if (ErrCode.MainsLostFault) return 1;
  if (ErrCode.GridVoltFault) return 2;
  if (ErrCode.GridFreqFault) return 3;
  if (ErrCode.PvVoltFault) return 4;
  if (ErrCode.IsolationFault) return 5;
  if (ErrCode.TemperatureOverFault) return 6;
  if (ErrCode.FanFault) return 7;
  if (ErrCode.OtherDeviceFault) return 8;
}

/*********************************************************************************************/

uint8_t solaxX1_send_retry = 0;
uint8_t solaxX1_nodata_count = 0;

void solaxX1250MSecond(void) // Every Second
{
  uint8_t value[61] = {0};
  bool data_ready = solaxX1_RS485ReceiveReady();

  if (protocolStatus.hasAddress && (data_ready || solaxX1_send_retry == 0))
  {
    if (data_ready)
    {
      uint8_t error = solaxX1_RS485Receive(value);
      if (error)
      {
        DEBUG_SENSOR_LOG(PSTR("SX1: Data response CRC error"));
      }
      else
      {
        solaxX1_nodata_count = 0;
        solaxX1_send_retry = 12;
        Energy.data_valid[0] = 0;

        solaxX1.temperature =    (float)((value[9] << 8) | value[10]); // Temperature
        solaxX1.energy_today =   (float)((value[11] << 8) | value[12]) * 0.1f; // Energy Today
        solaxX1.dc1_voltage =    (float)((value[13] << 8) | value[14]) * 0.1f; // PV1 Voltage
        solaxX1.dc2_voltage =    (float)((value[15] << 8) | value[16]) * 0.1f; // PV2 Voltage
        solaxX1.dc1_current =    (float)((value[17] << 8) | value[18]) * 0.1f; // PV1 Current
        solaxX1.dc2_current =    (float)((value[19] << 8) | value[20]) * 0.1f; // PV2 Current
        Energy.current[0] =      (float)((value[21] << 8) | value[22]) * 0.1f; // AC Current
        Energy.voltage[0] =      (float)((value[23] << 8) | value[24]) * 0.1f; // AC Voltage
        Energy.frequency[0] =    (float)((value[25] << 8) | value[26]) * 0.01f; // AC Frequency
        Energy.active_power[0] = (float)((value[27] << 8) | value[28]); // AC Power
        //temporal = (float)((value[29] << 8) | value[30]) * 0.1f; // Not Used
        solaxX1.energy_total =   (float)((value[31] << 8) | (value[32] << 8) | (value[33] << 8) | value[34]) * 0.1f; // Energy Total
        solaxX1.runtime_total =  (float)((value[35] << 8) | (value[36] << 8) | (value[37] << 8) | value[38]); // Work Time Total
        solaxX1.status =         (uint8_t)((value[39] << 8) | value[40]); // Work mode
        //temporal = (float)((value[41] << 8) | value[42]); // Grid voltage fault value 0.1V
        //temporal = (float)((value[43] << 8) | value[44]); // Gird frequency fault value 0.01Hz
        //temporal = (float)((value[45] << 8) | value[46]); // Dc injection fault value 1mA
        //temporal = (float)((value[47] << 8) | value[48]); // Temperature fault value
        //temporal = (float)((value[49] << 8) | value[50]); // Pv1 voltage fault value 0.1V
        //temporal = (float)((value[51] << 8) | value[52]); // Pv2 voltage fault value 0.1V
        //temporal = (float)((value[53] << 8) | value[54]); // GFC fault value
        solaxX1.errorCode =      (uint32_t)((value[58] << 8) | (value[57] << 8) | (value[56] << 8) | value[55]); // Error Code

        solaxX1.dc1_power = solaxX1.dc1_voltage * solaxX1.dc1_current;
        solaxX1.dc2_power = solaxX1.dc2_voltage * solaxX1.dc2_current;

        solaxX1_QueryLiveData();
        EnergyUpdateTotal(solaxX1.energy_total, true);  // 484.708 kWh
      }
    } // End data Ready

    if (0 == solaxX1_send_retry && 255 != solaxX1_nodata_count) {
      solaxX1_send_retry = 12;
      solaxX1_QueryLiveData();
    }

    // While the inverter has not stable ambient light, will send an address adquired but go offline again,
    // so no data will be received when the query is send, then we start the countdown to set the inverter as offline again.
    if (255 == solaxX1_nodata_count) {
      solaxX1_nodata_count = 0;
      solaxX1_send_retry = 12;
    }
  } // end hasAddress && (data_ready || solaxX1_send_retry == 0)
  else
  {
    if ((solaxX1_nodata_count % 4) == 0) { DEBUG_SENSOR_LOG(PSTR("SX1: No Data count: %d"), solaxX1_nodata_count); }
    if (solaxX1_nodata_count < 10 * 4) // max. seconds without data
    {
      solaxX1_nodata_count++;
    }
    else if (255 != solaxX1_nodata_count)
    {
      // no data from RS485, reset values to 0 and set inverter as offline
      solaxX1_nodata_count = 255;
      solaxX1_send_retry = 12;
      protocolStatus.status = 0b00001000; // queryOffline
      Energy.data_valid[0] = ENERGY_WATCHDOG;

      solaxX1.temperature = solaxX1.dc1_voltage = solaxX1.dc2_voltage = solaxX1.dc1_current = solaxX1.dc2_current = solaxX1.dc1_power = 0;
      solaxX1.dc2_power = solaxX1.status = Energy.current[0] = Energy.voltage[0] = Energy.frequency[0] = Energy.active_power[0] = 0;
      //solaxX1.energy_today = solaxX1.energy_total = solaxX1.runtime_total = 0;
    }
  }

  if (!protocolStatus.hasAddress && (data_ready || solaxX1_send_retry == 0))
  {
    if (data_ready)
    {
      // check address confirmation from inverter
      if (protocolStatus.inverterAddressSend)
      {
        uint8_t error = solaxX1_RS485Receive(value);
        if (error)
        {
          DEBUG_SENSOR_LOG(PSTR("SX1: Address confirmation response CRC error"));
        }
        else
        {
          if (value[6] == 0x10 && value[7] == 0x81 && value[9] == 0x06)
          {
            DEBUG_SENSOR_LOG(PSTR("SX1: Set hasAddress"));
            protocolStatus.status = 0b00100000; // hasAddress
          }
        }
      }

      // Check inverter serial number and send the set address request
      if (protocolStatus.queryOfflineSend)
      {
        uint8_t error = solaxX1_RS485Receive(value);
        if (error)
        {
          DEBUG_SENSOR_LOG(PSTR("SX1: Query Offline response CRC error"));
        }
        else
        {
          // Serial number from query response
          if (value[6] == 0x10 && value[7] == 0x80 && protocolStatus.inverterSnReceived == false)
          {
            for (uint8_t i = 9; i <= 22; i++)
            {
              data[i - 9] = value[i];
            }
            solaxX1_SendInverterAddress();
            protocolStatus.status = 0b1100000; // inverterSnReceived and inverterAddressSend
            DEBUG_SENSOR_LOG(PSTR("SX1: Set inverterSnReceived and inverterAddressSend"));
          }
        }
      }
    } // End data ready

    if (solaxX1_send_retry == 0)
    {
      if (protocolStatus.queryOfflineSend)
      {
        protocolStatus.status = 0b00001000; // queryOffline
        DEBUG_SENSOR_LOG(PSTR("SX1: Set Query Offline"));
      }
      solaxX1_send_retry = 12;
    }

    // request to the inverter the serial number if offline
    if (protocolStatus.queryOffline)
    {
      // We sent the message to query inverters in offline status
      source[0] = 0x01;
      destination[1] = 0x00;
      controlCode[0] = 0x10;
      functionCode[0] = 0x00;
      dataLength[0] = 0x00;
      solaxX1_RS485Send(9);
      protocolStatus.status = 0b00010000; // queryOfflineSend
      DEBUG_SENSOR_LOG(PSTR("SX1: Query Offline Send"));
    }
  } // end !hasAddress && (data_ready || solaxX1_send_retry == 0)

  if (!data_ready)
    solaxX1_send_retry--;
}

void solaxX1SnsInit(void)
{
  AddLog_P(LOG_LEVEL_DEBUG, PSTR("SX1: Solax X1 Inverter Init"));
  DEBUG_SENSOR_LOG(PSTR("SX1: RX pin: %d, TX pin: %d"), pin[GPIO_SOLAXX1_RX], pin[GPIO_SOLAXX1_TX]);
  protocolStatus.status = 0b00100000; // hasAddress

  solaxX1Serial = new TasmotaSerial(pin[GPIO_SOLAXX1_RX], pin[GPIO_SOLAXX1_TX], 1);
  if (solaxX1Serial->begin(SOLAXX1_SPEED)) {
    if (solaxX1Serial->hardwareSerial()) { ClaimSerial(); }
  } else {
    energy_flg = ENERGY_NONE;
  }
}

void solaxX1DrvInit(void)
{
  if ((pin[GPIO_SOLAXX1_RX] < 99) && (pin[GPIO_SOLAXX1_TX] < 99)) {
    energy_flg = XNRG_12;
  }
}

#ifdef USE_WEBSERVER
const char HTTP_SNS_solaxX1_DATA1[] PROGMEM =
    "{s}" D_SOLAX_X1 " " D_SOLAR_POWER "{m}%s " D_UNIT_WATT "{e}"
    "{s}" D_SOLAX_X1 " " D_PV1_VOLTAGE "{m}%s " D_UNIT_VOLT "{e}"
    "{s}" D_SOLAX_X1 " " D_PV1_CURRENT "{m}%s " D_UNIT_AMPERE "{e}"
    "{s}" D_SOLAX_X1 " " D_PV1_POWER "{m}%s " D_UNIT_WATT "{e}";
#ifdef SOLAXX1_PV2
const char HTTP_SNS_solaxX1_DATA2[] PROGMEM =
    "{s}" D_SOLAX_X1 " " D_PV2_VOLTAGE "{m}%s " D_UNIT_VOLT "{e}"
    "{s}" D_SOLAX_X1 " " D_PV2_CURRENT "{m}%s " D_UNIT_AMPERE "{e}"
    "{s}" D_SOLAX_X1 " " D_PV2_POWER "{m}%s " D_UNIT_WATT "{e}";
#endif
const char HTTP_SNS_solaxX1_DATA3[] PROGMEM =
    "{s}" D_SOLAX_X1 " " D_UPTIME "{m}%s " D_UNIT_HOUR "{e}"
    "{s}" D_SOLAX_X1 " " D_STATUS "{m}%s"
    "{s}" D_SOLAX_X1 " " D_ERROR "{m}%s";
#endif // USE_WEBSERVER

void solaxX1Show(bool json)
{
  char solar_power[33];
  dtostrfd(solaxX1.dc1_power + solaxX1.dc2_power, Settings.flag2.wattage_resolution, solar_power);
  char pv1_voltage[33];
  dtostrfd(solaxX1.dc1_voltage, Settings.flag2.voltage_resolution, pv1_voltage);
  char pv1_current[33];
  dtostrfd(solaxX1.dc1_current, Settings.flag2.current_resolution, pv1_current);
  char pv1_power[33];
  dtostrfd(solaxX1.dc1_power, Settings.flag2.wattage_resolution, pv1_power);
#ifdef SOLAXX1_PV2
  char pv2_voltage[33];
  dtostrfd(solaxX1.dc2_voltage, Settings.flag2.voltage_resolution, pv2_voltage);
  char pv2_current[33];
  dtostrfd(solaxX1.dc2_current, Settings.flag2.current_resolution, pv2_current);
  char pv2_power[33];
  dtostrfd(solaxX1.dc2_power, Settings.flag2.wattage_resolution, pv2_power);
#endif
  char temperature[33];
  dtostrfd(solaxX1.temperature, Settings.flag2.temperature_resolution, temperature);
  char runtime[33];
  dtostrfd(solaxX1.runtime_total, 0, runtime);
  char status[33];
  GetTextIndexed(status, sizeof(status), solaxX1.status, kSolaxMode);

  if (json)
  {
    ResponseAppend_P(PSTR(",\"" D_JSON_SOLAR_POWER "\":%s,\"" D_JSON_PV1_VOLTAGE "\":%s,\"" D_JSON_PV1_CURRENT "\":%s,\"" D_JSON_PV1_POWER "\":%s"),
                                solar_power, pv1_voltage, pv1_current, pv1_power);
#ifdef SOLAXX1_PV2
    ResponseAppend_P(PSTR(",\"" D_JSON_PV2_VOLTAGE "\":%s,\"" D_JSON_PV2_CURRENT "\":%s,\"" D_JSON_PV2_POWER "\":%s"),
                                pv2_voltage, pv2_current, pv2_power);
#endif
    ResponseAppend_P(PSTR(",\"" D_JSON_TEMPERATURE "\":%s,\"" D_JSON_RUNTIME "\":%s,\"" D_JSON_STATUS "\":\"%s\",\"" D_JSON_ERROR "\":%d"),
                                temperature, runtime, status, solaxX1.errorCode);

#ifdef USE_WEBSERVER
  }
  else
  {
    WSContentSend_PD(HTTP_SNS_solaxX1_DATA1, solar_power, pv1_voltage, pv1_current, pv1_power);
#ifdef SOLAXX1_PV2
    WSContentSend_PD(HTTP_SNS_solaxX1_DATA2, pv2_voltage, pv2_current, pv2_power);
#endif
    WSContentSend_PD(HTTP_SNS_TEMP, D_SOLAX_X1, temperature, TempUnit());
    char errorCodeString[33];
    WSContentSend_PD(HTTP_SNS_solaxX1_DATA3, runtime, status,
      GetTextIndexed(errorCodeString, sizeof(errorCodeString), solaxX1_ParseErrorCode(solaxX1.errorCode), kSolaxError));
#endif  // USE_WEBSERVER
  }
}

/*********************************************************************************************\
 * Interface
\*********************************************************************************************/

bool Xnrg12(uint8_t function)
{
  bool result = false;

  switch (function) {
    case FUNC_EVERY_250_MSECOND:
      if (uptime > 4) { solaxX1250MSecond(); }
      break;
    case FUNC_JSON_APPEND:
      solaxX1Show(1);
      break;
#ifdef USE_WEBSERVER
    case FUNC_WEB_SENSOR:
      solaxX1Show(0);
      break;
#endif  // USE_WEBSERVER
    case FUNC_INIT:
      solaxX1SnsInit();
      break;
    case FUNC_PRE_INIT:
      solaxX1DrvInit();
      break;
  }
  return result;
}

#endif  // USE_SOLAX_X1_NRG
#endif  // USE_ENERGY_SENSOR